Apparatus and method for the treatment of tissue with ultrasound energy by direct contact

ABSTRACT

Apparatus and method for the treatment of tissue, such as hard and soft tissues, wounds, tumors, muscles, and cartilage, through the direct contact of ultrasound energy is disclosed. Ultrasound energy is delivered to a target area through direct contact with an ultrasound tip. Ultrasound energy is also delivered through direct contact with a coupling medium. The ultrasound tip is specially designed to comprise of a cavity area for controlled fragmentation and the simultaneous sonication of a target area. The specially designed ultrasound tip allows for ultrasound energy to focus on a target area. The ultrasound apparatus may be moved in a variety of different directions during the treatment of tissue.

BACKGROUND OF THE INVENTION

1. Field of the Invention

The present invention relates to apparatus and method for the treatment of tissue, such as hard and soft tissue, wounds, tumors, muscles, and cartilage, with ultrasound energy by direct contact.

2. Description of the Related Art

There are a variety of known methods for the treatment of tissue. These methods include wound dressings, hyperbaric oxygen treatment, growth factor therapy, antibiotics, surgery, physical therapy, vacuum therapy, electrical stimulation, bioengineered tissue, ultraviolet light therapy, and tissue ultrasound. There are also a variety of known methods for the treatment of wounds with ultrasound energy.

U.S. patents that disclose devices and methods for wound treatment using an ultrasound spray include: U.S. Pat. No. 6,478,754 to Babaev; U.S. Pat. No. 6,761,729 to Babaev; U.S. Pat. No. 6,533,803 to Babaev; U.S. Pat. No. 6,569,099 to Babaev; U.S. Pat. No. 6,663,554 to Babaev; and finally U.S. Pat. No. 6,960,173 to Babaev. These devices and methods can only achieve limited results because there is no sufficient delivery of ultrasound energy to the target because there is no direct contact with the target area. U.S. Pat. No. 7,025,735 to Soring and U.S. Pat. No. 6,916,296 also to Soring disclose a method and device for the treatment of septic wounds that uses both a liquid aerosol and direct contact.

U.S. Patent Application 2004/0030254 to Babaev discloses a device and method for ultrasound wound debridement. Babaev discloses a device that causes debridement through mechanical vibration in the ultrasound tip. This device is also limited in that it uses only mechanical vibration for debridement.

Therefore, there is a need for a device and method that can use both mechanical vibration and ultrasound cavitation for fragmentation. There is also a need for a device and method that can simultaneously treat tissue and remove unwanted tissue through fragmentation.

SUMMARY OF THE INVENTION

The present invention is directed towards apparatus and method for the treatment of tissue, such hard and soft tissues, wounds, tumors, muscles, and cartilage, through the direct contact of ultrasound energy. Apparatus and methods in accordance with the present invention may meet the above-mentioned needs and also provide additional advantages and improvements that will be recognized by those skilled in the art upon review of the present disclosure.

The present invention comprises an ultrasound transducer with a specially designed ultrasound tip for the treatment of tissue. The tip is specially designed for controlled fragmentation and the simultaneous sonication of a target area, such as a wound, bone, unwanted tissue layers, an infected area, via direct contact. The tip is also specially designed to focus ultrasound energy on a target area. The tip is comprised of a cavity area—as used herein, the term “cavity area” means a hollowed out area. An example of an ultrasound tip with a cavity area is where the combination of an ultrasound horn and ultrasound tip forms a shape similar to a spoon utensil, where one side of the cavity area is concave and the other side is convex. Other comparable shapes or combination of shapes such as conical or polygonal may be similarly effective. The cavity area may be located on the radial sides at the distal end of the radiation surface. Additionally, the radiation surface at the distal end may form a tilted cavity area. The edges and surfaces of the ultrasound tip may be smooth, rough/jagged, or any combination thereof. The ultrasound tip may also be comprised of an orifice or orifices for the delivery and/or extraction of a coupling medium during treatment. The orifice or orifices may also be used to extract the fragmented unwanted tissue.

The specially designed ultrasound tip may be used for the treatment tissue, including the treatment of wounds and the removal of tumors. Ultrasound energy is generally delivered from the radial side of the specially designed ultrasound tip. The ultrasound energy may be delivered directly by contacting the target area with the ultrasound tip. The ultrasound energy may also be delivered directly by contacting the target area with a coupling medium such as a fluid flow that may emanate out of the orifice or orifices. Coupling medium, as used herein, is any medium through which ultrasound energy is capable of traveling except for a mist, aerosol spray, or atomized liquid. The use of ultrasound energy with a coupling medium may help fragment tissue through both mechanical vibration and cavitation. There are different treatment methods where the ultrasound apparatus may be moved in various directions such as latitudinal, longitudinal, rotational, vertical or any other similar movement or combination of movements.

The use of ultrasound energy may have multiple beneficial effects that include, but are not limited to, destroying bacteria, disinfecting a wound, stimulating cell growth, increasing blood flow, precise fragmentation of unwanted tissue, painless fragmentation of a wound, exerting less pressure on a wound as compared to mechanical cleansing, and treating fistula and cavities. These effects may aid in the healing process of wounds.

The invention is related to method and device for the treatment of hard and soft tissue, including wound treatment, through the direct contact of ultrasound energy.

One aspect of this invention may be to provide a method and device for more effective treatment of tissue by delivering ultrasound energy by directly contacting the target area.

Another aspect of the invention may be to provide a method and device for more efficient treatment tissue.

Another aspect of the invention may be to provide a method and device for quicker treatment of tissue.

Another aspect of the invention may be to provide a method and device that may exert less pressure on the target area during the treatment of tissue.

Another aspect of the invention may be to provide a method and device that allows for controllable fragmentation.

Another aspect of the invention may be to provide a method and device that destroys bacteria.

Another aspect of the invention may be to provide a method and device for the stimulation of tissue cell growth.

Another aspect of the invention may be to provide a method and device to increase blood flow.

Another aspect of the invention may be to provide a method and device for pain relief.

Another aspect of the invention may be to provide a method and device for cleansing wounds.

Another aspect of the invention may be to provide a method and device for cleansing internal and external post-operation areas.

Another aspect of the invention may be to provide a method and device treating fistula and cavities.

These and other aspects of the invention will become more apparent from the written descriptions and figures below.

BRIEF DESCRIPTION OF THE DRAWINGS

The present Invention will be shown and described with reference to the drawings of preferred embodiments and clearly understood in details.

FIG. 1 is a perspective view an ultrasound apparatus for the treatment of tissue use according to the present invention.

FIG. 2 a is a cross-sectional view of an ultrasound apparatus for the treatment of tissue shown in FIG. 1.

FIG. 2 b is a cross-sectional view of an ultrasound apparatus with a rear entry port.

FIG. 2 c is a cross-sectional view of an ultrasound apparatus with a radial entry port.

FIG. 2 d is a cross-sectional view of an ultrasound apparatus with a rear entry port and a radial exit port.

FIG. 2 e illustrates a cross-sectional view of an ultrasound apparatus with a radial entry port and a radial exit port.

FIG. 2 f illustrates a cross-sectional view of an ultrasound apparatuse with a rear entry port and two radial exit ports.

FIG. 3 is a detailed cross-sectional schematic representation of the delivery of ultrasound energy

FIGS. 4 a-4 c are an example tissue treatment method using an ultrasound apparatus.

FIGS. 5 a-5 c are front cross-sectional views of the tissue treatment method with the ultrasound apparatus from FIGS. 4 a-4 c.

FIGS. 6 a-6 c are alternative methods and embodiments of an ultrasound tissue treatment apparatus that comprises at least one orifice on the back surface of an ultrasound tip.

FIGS. 7 a-7 c are different embodiments of an ultrasound tip with a cavity area.

FIG. 8 are front cross-sectional views of variety of configurations on the number of orifices on an ultrasound tip.

FIG. 9 are perspective views of a variety of configurations of the edges and back surface of an ultrasound tip

FIG. 10 is a cross-sectional view an ultrasound tip with a polygonal cavity area.

DETAILED DESCRIPTION OF THE INVENTION

The present invention is a method and device for the treatment of tissue through the direct contact of ultrasound energy. Preferred embodiments of the present invention in the context of an apparatus and methods are illustrated in the figures and described in detail below.

FIG. 1 is a perspective view an ultrasound apparatus for use according to the present invention that comprises an ultrasound generator 1, a transducer 2, an ultrasound transducer 3, an ultrasound horn 4, and a specially designed ultrasound tip 5. The ultrasound generator 1 may be battery powered or powered through an electrical outlet.

FIG. 2 a illustrates a cross-sectional view of an ultrasound apparatus for the treatment of tissue as shown in FIG. 1. The ultrasound apparatus comprises an ultrasound transducer 3 that is mechanically connected to the ultrasound horn 4 by threading or other means 6. The ultrasound horn 4 is mechanically connected to the ultrasound tip 5 by threading or other means 7. The preferred embodiment comprises an ultrasound transducer 3 that is connected to the ultrasound horn 4 by a mechanical interface; alternative embodiments could have the ultrasound transducer 3 directly connected to the ultrasound horn 4 to comprise a single piece without a mechanical interface. The preferred embodiment also comprises an ultrasound horn 4 that is connected to the ultrasound tip 5 by a mechanical interface; alternative embodiments could have the ultrasound horn 4 directly connected to the ultrasound tip 5 to comprise a single piece without a mechanical interface.

FIG. 2 b is a cross-sectional view of an ultrasound apparatus for the treatment of tissue that comprises a rear entry port 8. The rear entry port 8 is located at the proximal end of the transducer 3. The apparatus also comprises an entry lumen 9 that connects the rear entry port 8 to an exit orifice 10 that is located on the ultrasound tip 5. A coupling medium may be inserted into the rear entry port 8. The preferred coupling medium to use is a fluid. Fluid is inserted in the rear entry port 8 and moves through the entry lumen 9, and then is delivered from the entry orifice 10. A tube or other material can replace a lumen 9. Fluid may be delivered from the entry orifice 10 to a target treatment area. The preferred method of treatment is to deliver a liquid flow to a target area from the entry orifice 10.

FIG. 2 c is a cross-sectional view of an ultrasound apparatus for the treatment of tissue that comprises a radial entry port 11. The radial entry port 11 is located on a radial side of the ultrasound horn 4. The radial entry port 11 may be perpendicular to or any other angle to the axis of the ultrasound horn 4. The preferred alignment for the radial entry port 11 is perpendicular to the ultrasound horn 4. The apparatus also comprises an entry lumen 12 that connects the radial entry port 11 to an entry orifice 10 that is located on the ultrasound tip 5. Fluid is inserted into the radial entry port 11, moves through the entry lumen 12, and then is delivered from the entry orifice 10. Fluid may be delivered from the entry orifice 10 to the target treatment area.

FIG. 2 d is a cross-sectional view of an ultrasound apparatus for the treatment of tissue that comprises rear entry port 8 and a radial exit port 15. The rear entry port 8 is located at the proximal end of the transducer 3, and the radial exit port 15 is located on a radial side of the ultrasound horn 4. The apparatus also comprises an entry lumen 9 that connects the rear entry port 8 to an entry orifice 10 that is located on the ultrasound tip 5. Fluid is inserted in the rear entry port 8, moves through the entry lumen 9, and then is delivered from the entry orifice 10. Fluid may be delivered from the entry orifice 10 to a target treatment area. Fluid may also be extracted from the treatment area through exit orifice 13 that is also located on the ultrasound tip 5. Exit orifice 13 is connected to radial exit port 15 by exit lumen 14. Fluid enters the exit orifice 13, travels through the exit lumen 14, and exits out of the radial exit port 15. Fluid may be extracted from the treatment area in order to continually supply the treatment area with fresh fluid. Fragmented tissue may also be extracted along with the fluid. The preferred embodiment of an ultrasound apparatus for the treatment of tissue comprises a rear entry port and a radial exit port. Alternative embodiments, as described below, may comprise multiple entry and/or exit ports that may be located at different locations with different alignments along the ultrasound apparatus. The preferred embodiment also comprises an entry orifice and an exit orifice. Alternative embodiments may comprise no orifices, one orifice, or multiple orifices.

FIG. 2 e illustrates a cross-sectional view of an ultrasound apparatus for the treatment of tissue that comprises radial entry port 11 and a radial exit port 15. The radial entry port 11 is located on a radial side of the ultrasound horn 4, and the radial exit port 15 is located on a radial side of the ultrasound horn 4. The preferred embodiment comprises a radial exit port 15 located on the direct opposite side of the ultrasound horn 4 than the radial entry port 11 with both the exit port 15 and entry port 11 aligned at ninety-degrees to the axis of the horn 4. Alternate embodiments could have an entry port 11 and exit port 15 positioned at any other location on the ultrasound horn 4 or aligned at any other angle to the axis of the horn 4. The apparatus also comprises an entry lumen 12 that connects the radial entry port 11 to an entry orifice 10 that is located on the ultrasound tip 5. Fluid is inserted in the radial entry port 11, moves through the entry lumen 12, and then is delivered from the entry orifice 10. Fluid may be delivered from the entry orifice 10 to the target treatment area. Fluid may also be extracted from the treatment area through an exit orifice 13 that is also located on the ultrasound tip 5. Exit orifice 13 is connected to the radial exit port 15 by exit lumen 14. Fluid enters the exit orifice 13, travels through the exit lumen 14, and exits out of the radial exit port 15. Fluid may be extracted from the treatment area in order to continually supply the treatment area with fresh fluid. Fragmented tissue may also be extracted along with fluid.

FIG. 2 f illustrates a cross-sectional view of an ultrasound apparatus for the treatment of tissue that comprises a rear entry port 8 and two radial exit ports 16 and 17. The rear entry port 8 is located at the proximal end of the transducer 3, one radial exit port 16 is located on a radial side of the ultrasound horn 4, and another radial exit port 17 is also located on a radial side of the ultrasound horn 4. The preferred embodiment comprises of a radial exit port 16 located on the direct opposite side of the ultrasound horn 4 than the radial exit port 17 with both exit port 16 and exit port 17 aligned at ninety-degrees to the axis of the horn 4. Alternative embodiments could have exit port 16 and exit port 17 positioned at any other location on the ultrasound horn 4 or aligned at any other angle to the axis of the horn 4. This embodiment also comprises an entry lumen 9 that connects the rear entry port 8 to an entry orifice 10 that is located on the ultrasound tip 5. Fluid is inserted in the rear entry port 8, moves through the entry lumen 9, and then is delivered from the entry orifice 10. Fluid may delivered from the entry orifice 10 to a target treatment area. Fluid may also be extracted from the treatment area through exit orifice 20 and exit orifice 21 that are also located on the ultrasound tip 5. Exit orifice 20 and exit orifice 21 are connected to radial exit port 16 and radial exit port 17 by exit lumen 18 and exit lumen 19, respectively. Fluid enters exit orifice 20 and exit orifice 21, travels through exit lumen 18 and exit lumen 19, and exits out of radial exit port 16 and radial exit port 17. Fluid may be extracted from the treatment area in order to continually supply the treatment area with fresh fluid. Fragmented tissue may also be extracted along with fluid.

FIG. 3 is a detailed cross-sectional schematic representation of the delivery of ultrasound energy a fluid from an ultrasound tip 5 that comprises an entry port and exit port (not shown). The ultrasound tip 5 is specially designed to deliver focused ultrasound energy. The ultrasound tip 5 in this embodiment comprises a cavity area located on the radial sides at the distal end of the radiation surface. The cavity area is shaped similar to the tip of a spoon utensil, where the open side of the cavity area is concave and the back side of the cavity area is convex. The shape of the ultrasound tip 5 in this embodiment allows for the ultrasound energy 23 emanating from the tip 5 to focus 24 on the target area 25. The ultrasound energy 23 travels through the fluid 22 to the target area 25. The fluid 22 is delivered to the target area 25 from the entry orifice 10. The fluid 22 travels in a vortex motion 26: fluid 22 is delivered from the entry orifice 10, strikes the side of the open cavity, and then circles back around. The fluid 22 may then be extracted out of the exit orifice 13. It may be beneficial to extract the used fluid 22 from the treatment area 25 while delivering a fresh fluid 22 to the treatment area 25. The shape of the ultrasound tip in FIG. 3 is the preferred embodiment. Alternative embodiments of a cavity area may comprise comparable shapes or combination of shapes such as conical or polygonal that may also be effective at focusing ultrasound energy. The cavity area may be located on the radial sides at the distal end of the radiation surface. Additionally, the radiation surface at the distal end may form a titled cavity area. The preferred location of the cavity area is on the radial sides at the distal end of the radiation surface.

FIGS. 4 a-4 c are an example tissue treatment method using an ultrasound apparatus according to the present invention. FIG. 4 a depicts the first motion whereby the edges 27 of the ultrasound tip 5 are dragged across the treatment area 25 while delivering ultrasound energy 23 from the open cavity area, where the ultrasound energy 23 focuses 24 on the treatment area 25. While the tip 5 is moved longitudinally, the fluid 22 may be delivered from the entry orifice 10, where the fluid 22 would travel in a vortex motion 26 across the treatment area 25. Unwanted tissue 28 is fragmented from the treatment area 25 due to the mechanical vibration in the ultrasound tip 5 and the cavitation that occurs by delivering ultrasound energy 23 through the fluid 22. The used fluid and fragmented tissue may be extracted through the exit orifice 13. FIG. 4 b depicts that as the ultrasound tip 5 is moved longitudinally across the treatment area 25, the ultrasound tip 5 is rotated along the axis of the ultrasound horn 4. Ultrasound energy 29 may be delivered from the external side of the open cavity in the ultrasound tip 5 to the treatment area 25. FIG. 4 c shows the ultrasound tip 5 after it been rotated 180 degrees. Ultrasound energy 30 may be delivered from the back surface 31 of the ultrasound tip 5; the back surface 31 is the side of the ultrasound tip 5 that is opposite the cavity area. The ultrasound energy that is delivered during this movement is generally radial waves because the ultrasound energy that reaches that target area 25 is mostly from the radial side of the ultrasound tip 5; however, some shear and longitudinal waves may reach the target area 25. The ultrasound tip 5 may also be moved latitudinally across the treatment area before, during, or after the longitudinal and rotational movement.

FIGS. 5 a-5 c are front cross-sectional views of ultrasound tips 5 from the corresponding FIGS. 4 a-4 c, respectively. FIG. 5 a shows the corresponding front cross-sectional view of FIG. 4 a where the edges 27 of the ultrasound tip 5 are dragged longitudinally across the treatment area 25 while ultrasound energy 23 is delivered from the open cavity area to the treatment area 25. Fluid 22 may be delivered from the entry orifice 10. Unwanted tissue 28 is fragmented from the treatment area 25 due to the mechanical vibration in the ultrasound tip 5 and the cavitation that occurs by delivering ultrasound energy 23 through the fluid 22. FIG. 5 b shows the corresponding front cross-sectional view of FIG. 4 b where the ultrasound tip 5 is rotated along the axis of the horn. Ultrasound energy 29 may be delivered from the external side of the open cavity on the ultrasound tip 5. Unwanted tissue 28 may be fragment from the delivery of the ultrasound energy 29 and the mechanical vibration in the ultrasound tip 5. FIG. 5 c shows the corresponding front cross-sectional view of FIG. 4 c where the ultrasound energy 30 may be delivered from the back surface 31 of the ultrasound tip 5 to the treatment area 25.

FIGS. 6 a-6 c are alternative methods and embodiments of an ultrasound tissue treatment apparatus that comprises at least one orifice on the back surface of an ultrasound tip. FIG. 6 a shows an alternative embodiment of an ultrasound apparatus that is comprised of a back orifice 32 on the back surface 33 of an ultrasound tip 5. The back orifice 32 can be used to extract fragmented tissue 28 from the target area 25 through the exit orifice 13. The entry orifice 10 may still be used to deliver a fluid 22 to the target area 25. The fluid 22 may also be delivered to the target area 25 through the back orifice 32; in that instance, a back orifice or orifices may be used to deliver to and extract from the target area 25 a fluid 22. The fluid 22 may still travel in a vortex motion 26 as it is delivered from the entry orifice 10. The fluid 22 may also be delivered directly to the target area 25 if the open cavity area on the ultrasound tip 5 is facing the target area 25. One possible method with this embodiment is depicted in FIG. 6 a where the back surface 33 of the ultrasound tip 5 is moved longitudinally across the target area 25 during delivery of ultrasound energy 30 from the back surface 33 while either simultaneously or sequentially lifting and lowering the proximal end of the ultrasound apparatus so that different parts of the back surface 33, such as the proximal end, the middle, and the distal end, may contact the target area 25.

FIG. 6 b is an alternative method that may be used with an ultrasound tip that has at least one back orifice. The movement in this method is similar to the movement in the method depicted in FIGS. 4 a-4 c and FIGS. 5 a-5 c. The ultrasound tip 5 is moved in a latitudinal direction across the treatment area 25 while either simultaneously or sequentially rotating the ultrasound tip 5 so that different sections of the back surface 33 may contact the target area 25. In this method, the ultrasound tip 5 may also be lifted and/or moved in a longitudinal direction across the treatment area during delivery of ultrasound energy 30. FIG. 6 c is an alternative embodiment of the ultrasound apparatus depicted in FIG. 6 a. This embodiment comprises multiple back orifices 34 on back surface 35.

FIGS. 7 a-7 c are different embodiments of an ultrasound tip 5 with a cavity area. FIG. 7 a is an ultrasound tip 5 where the radial sides at the distal end of the radiation surface forms a cavity area that is in a shape similar to the tip of a spoon. The cavity area, in this embodiment, is parallel to the axis of the ultrasound horn 4. This is the preferred embodiment. Alternative embodiments of the ultrasound tip 5 are shown in FIGS. 7 b and 7 c where the radiation surface at the distal end forms a titled cavity area, whereby the cavity area is also in a shape similar to that of the tip of a spoon. The cavity areas, in these embodiments, are at angle titled to the axis of the ultrasound horn 4. The preferred embodiment is shown in FIG. 7 a where the radial sides at the distal end of the radiation surface forms a cavity area that is in a shape similar to the tip of a spoon. Other comparable shapes or combination of shapes for alternative embodiments, in addition to those in FIGS. 7 a and 7 c, of an ultrasound tip that comprises a cavity area may be similarly effective.

FIG. 8 are front cross-sectional views of various embodiments of an ultrasound tip 5. The ultrasound tip 5 may contain no orifices, one orifice, or multiple orifices. The orifices may also be the same or different sizes. The preferred embodiment is to have the exit orifice for extraction larger than the entry orifice for delivery.

FIG. 9 are different embodiments of the edges 27 and back surface 33 of an ultrasound tip according to the present invention. The edges 27 of the ultrasound tip 5 may be smooth, non-smooth, or any combination thereof. The preferred embodiment comprises rough/jagged edges 27. The back surface 33 may be smooth, non-smooth, or any combination thereof. The preferred embodiment comprises a rough/jagged back surface 33.

FIG. 10 is an alternative embodiment of an ultrasound tip with a cavity area. This embodiment is comprised of a polygonal-shaped cavity area 36. The preferred embodiment is the concave-convex spoon shaped open cavity that is described and depicted above. Alternative embodiments of an open cavity may be similarly effective in delivering ultrasound energy.

The ultrasound apparatus shown in FIG. 1 delivers ultrasound energy to a target area for the treatment of tissue, including the treatment of the wounds and the removal of tumors. The tip is specially designed for controlled fragmentation and the simultaneous sonication of a target area via direct contact. The tip is also specially designed to focus ultrasound energy on a target area. The use of ultrasound energy may have multiple beneficial effects that include, but are not limited to, destroying bacteria, disinfecting a wound, stimulating cell growth, increasing blood flow, exerting less pressure on a wound, treating fistula and cavities, and removing unwanted tissue. These effects may aid in the healing process of wounds.

There are multiple methods that may be used to deliver ultrasound energy to a target area. Ultrasound energy may be delivered directly by contacting the target area with the ultrasound tip from areas such as the edges or back surface area of the tip. Ultrasound energy may also be delivered directly by contacting the target area with a coupling medium. The ultrasound energy is generally delivered from the radial side of the ultrasound tip, but it may also be delivered from the distal end of the ultrasound tip. Therefore, the ultrasound energy that is mainly delivered is radial waves. The use of radial waves, as compared to longitudinal waves from the distal end, may allow for a horizontal vibration in the ultrasound tip on the target area rather than a vertical vibration.

The preferred coupling medium to use is a fluid, and the preferred fluid to use is saline. Other fluids such as drugs, antibiotics, antiseptics, etc may also be used. Both micro and macro cavitation may occur from the delivery of ultrasound energy through the coupling medium. Macro cavitation occurs in the coupling medium and results in sterilizing the target surface, fragmenting tissue, and mechanical cleansing because of the cavitation effect. Micro cavitation creates microstreaming inside tissue, which is beneficial for tissue granulation. Fragmentation of unwanted tissue may result from both the cavitation that occurs and the mechanical vibration of the ultrasound tip on the target area.

The ultrasound tip may comprise an orifice or orifices that may deliver a coupling medium such as a liquid flow to the target area. The orifice or orifices may also be used to extract a coupling medium that is delivered to the target area. The orifice or orifice may be located anywhere on the ultrasound tip; the preferred embodiment comprises an orifice or orifice that is located on the proximal end of cavity area.

The ultrasound tip may be held flat against the target area during treatment or it may be held at an angle. During the treatment, the ultrasound tip, or any portion thereof, may be moved latitudinally, moved longitudinally, rotated, lifted, or any combination thereof. If the ultrasound tip is rotated during treatment, then ultrasound energy may be delivered from the cavity area, the external sides of the cavity area, and the back surface of the cavity area. If the ultrasound tip is lifted during treatment, then ultrasound energy may be delivered from both the radial side of the ultrasound tip and the distal end of the ultrasound tip.

One preferred method of treatment is to hold the distal end of the ultrasound tip against the target with the cavity area facing the target, while holding the proximal end of the horn above the target, and move the tip longitudinally while delivering and extracting liquid from orifices in the ultrasound tip.

Another preferred method of treatment is to hold one edge of the peripheral boundary of the cavity area against the target with the other edge of the peripheral boundary of the cavity area just above the target, and then move the ultrasound tip latitudinally. Liquid saline is delivered and extracted from an orifice or orifices in this preferred embodiment. Furthermore, while the ultrasound tip is being moved, the ultrasound apparatus/tip may be rotated during delivery so that the cavity area of the tip is no longer facing the target; ultrasound energy is then being delivered from the sides and then the back surface of the cavity area.

The intensity of the ultrasound energy can be controlled through a variation in the ultrasound parameters such as the frequency, the amplitude, and the treatment time. The frequency range for the ultrasound energy is 15 kHz to 20 MHz. The preferred low-frequency ultrasound range is 20 kHz-100 kHz, the more preferred low-frequency ultrasound range is 25 kHz-50 kHz, and the recommend low-frequency ultrasound value is 30 kHz. The preferred high-frequency ultrasound range is 0.7 MHz-3 MHz, the more preferred high-frequency ultrasound range is 0.7 MHz-3 MHz, and the recommend high-frequency ultrasound value is 0.7 MHz. The amplitude of the low-frequency ultrasound energy can be 5 microns and above, with the preferred low-frequency amplitude to be in range of 30 microns to 100 microns, and the recommended low-frequency amplitude value is 100 microns. The amplitude of the high-frequency ultrasound energy can be 1 micron and above, with the preferred high-frequency amplitude to be at least 5 microns, and the recommended high-frequency amplitude value is 10 microns. The preferred method of treatment uses low-frequency ultrasound.

There are a variety of factors that may influence the treatment time. These factors may include the type of tissue being treated, the condition of a wound, the size of a wound, and the location of a wound.

Although specific embodiments and methods of use have been illustrated and described herein, it will be appreciated by those of ordinary skill in the art that any arrangement that is calculated to achieve the same purpose may be substituted for the specific embodiments and methods shown. It is to be understood that the above description is intended to be illustrative and not restrictive. Combinations of the above embodiments and other embodiments as well as combinations of the above methods of use and other methods of use will be apparent to those having skill in the art upon review of the present disclosure. The scope of the present invention should be determined with reference to the appended claims, along with the full scope of equivalents to which such claims are entitled. 

1) An apparatus for the treatment of tissue with ultrasound energy by direct contact, comprising: a) a generator and a transducer for generating ultrasound energy; b) an ultrasound horn and ultrasound tip for delivering ultrasound energy; c) wherein the radial sides at the distal end of the radiation surface forms a cavity area or wherein the radiation surface at the distal end forms a tilted cavity area; d) wherein the ultrasound tip delivers ultrasound energy to a target area; and e) wherein the ultrasound energy has an intensity capable of treating tissue. 2) The apparatus according to claim 1, wherein the generator and transducer generate the ultrasound energy with particular ultrasound parameters indicative of an intensity capable of treating tissue. 3) The apparatus according to claim 1, wherein the ultrasound frequency is in the approximate range of 15 kHz-20 MHz. 4) The apparatus according to claim 1, wherein the preferred low-frequency ultrasound is in the approximate range of 20 kHz-100 kHz. 5) The apparatus according to claim 1, wherein the more preferred low-frequency ultrasound is in the approximate range of 25 kHz-50 kHz. 6) The apparatus according to claim 1, wherein the recommended low-frequency ultrasound value is approximately 30 kHz. 7) The apparatus according to claim 1, wherein the preferred high-frequency ultrasound is in the approximate range of 0.7 MHz-3 MHz. 8) The apparatus according to claim 1, wherein the more preferred high-frequency ultrasound is in the approximate range of 0.7 MHz-1 MHz. 9) The apparatus according to claim 1, wherein the recommended high-frequency ultrasound value is approximately 0.7 MHz. 10) The apparatus according to claim 1, wherein the low-frequency ultrasound amplitude is at least 1 micron. 11) The apparatus according to claim 1, wherein the preferred low-frequency ultrasound amplitude range is approximately 30-250 microns. 12) The apparatus according to claim 1, wherein the recommended low-frequency ultrasound amplitude value is approximately 100 microns. 13) The apparatus according to claim 1, wherein the high-frequency ultrasound amplitude is at least 1 micron. 14) The apparatus according to claim 1, wherein the preferred high-frequency ultrasound amplitude is at least 5 microns. 15) The apparatus according to claim 1 wherein the recommended high-frequency ultrasound amplitude value is approximately 10 microns. 16) The apparatus according to claim 1, wherein the combination of an ultrasound horn and ultrasound tip form a shape similar to a spoon. 17) The apparatus according to claim 1, further comprised of an orifice or orifices. 18) The apparatus according to claim 17, wherein the orifice or orifices are located on the proximal end of the cavity area, on the distal end of the cavity area, on the middle of the cavity, or any combination thereof. 19) The apparatus according to claim 17, wherein the orifice or orifices are capable of delivering and/or extracting a coupling medium. 20) The apparatus according to claim 17, wherein the orifice or orifices are capable of extracting fragmented tissue. 21) The apparatus according to claim 1, wherein the transducer contains a radiation surface intended to achieve delivery of the ultrasound energy with an intensity capable of treating tissue. 22) The apparatus according to claim 1, wherein the transducer includes a radiation surface having a surface area dimensioned/constructed for achieving delivery of the ultrasound energy with an intensity capable of treating tissue. 23) The apparatus according to claim 1, wherein shape of the peripheral boundary of the cavity area is circular, oval, elliptical, or any other comparable shape or combination of shapes. 24) The apparatus according to claim 23, wherein the shape of the peripheral boundary of the cavity area of the radiation surface is intended to achieve delivery of the ultrasound energy with an intensity capable of treating tissue. 25) The apparatus according to claim 1, wherein the shape of the peripheral boundary of the distal end of the radiation surface is circular, oval, elliptical, polygonal, a straight-line, a non-straight line, or another comparable shape or combination of shapes. 26) The apparatus according to claim 25, wherein the shape of the peripheral boundary of distal end of the radiation surface is intended to achieve delivery of the ultrasound energy with an intensity capable of treating tissue. 27) The apparatus according to claim 1, wherein the edges of the radiation surface are smooth, non-smooth, or any combination thereof. 28) The apparatus according to claim 1, wherein the back surface area of the radiation surface is smooth, non-smooth, or any combination thereof. 29) The apparatus according to claim 1, wherein the transducer is driven by a continuous or pulsed frequency. 30) The apparatus according to claim 1, wherein the transducer is driven by a fixed or modulated frequency. 31) The apparatus according to claim 1, wherein the driving wave form of the transducer is selected from the group consisting of sinusoidal, rectangular, trapezoidal and triangular wave form. 32-87. (canceled) 